DE112010005769B4 - transformer - Google Patents

Abstract

A transformer comprising: a magnetic member having a plate-like portion, an outer leg portion protrudingly provided on one side on a surface of the plate-like portion in a direction perpendicular to the plate-like portion, and a columnar leg portion projecting in a protruding manner a center of the surface of the plate-like portion is provided; a plurality of coils each forming a tubular portion into which the columnar leg portion of the magnetic member is inserted and having a flange at one end of the tubular portion; and a plurality of windings wound around the respective tubular portions of the plurality of coils; wherein the tubular portion of a coil as a part of the plurality of coils has a shape to be inserted into the tubular portion of another coil from the side of the flange, and wherein the coil is in a spiral shape having one end on the side of the periphery and an end is formed on the side of the tubular portion, and wherein the end of the coil is disposed on the side of the tubular portion which is interposed between the coil into which the tubular portion is inserted and the coil inserted therein being pulled outwardly through a gap between the tubular portions of the spool into which the tubular portion is inserted and the spool to be inserted therein; wherein on the transformer further a notch is provided at a position in contact with the columnar leg portion of the plate-like portion of the magnetic member, and wherein in the tubular portion of the coil as a portion having the flange at the one end, an extended portion which covers the notch of the magnetic member is provided at the other end of the tubular portion.

Description

TECHNICAL AREA

The present invention relates to a high voltage transformer sheet insulating the primary side from the secondary side.

STATE OF THE ART

According to a trend to reduce emissions of carbon dioxide, a small amount of emissions from an electric vehicle is accepted and the electric vehicle begins to spread due to an increasing demand for it.

A circuit in which a high voltage of, for example, 400 V is provided which does not exist in a known gasoline engine vehicle is disposed in the electric vehicle. Heretofore, a high voltage circuit has been mainly connected to a power source supplied with an AC line, and in such an application, the circuit has been increased in efficiency and reduced in size in its own way. However, when the high voltage circuit is placed in the electric vehicle, a further increase in efficiency and a further reduction in size are needed for the circuit. In particular, a transformer is a large component in a circuit of a power supply system, and therefore, a reduction in the size of the transformer is required. Conventionally, there is a transformer sheet in which the coil is formed in a sheet shape as a measure for reducing the size of the transformer, in particular, examples of a high voltage resistant transformer sheet are disclosed in Patent Documents 1 and 2, which are discussed below.

A transformer sheet disclosed in Patent Document 1 is related to a step-up transformer which generates a high voltage for illuminating a cold cathode lamp and guides a projection of a secondary winding for generating a high voltage toward a terminal portion through a notch prepared in a core to be separated from the other winding sections by a distance, thereby ensuring a dielectric strength thereof.

A transformer sheet disclosed in Patent Document 2 relates to a transformer that generates a high voltage firing pulse for starting a discharge lamp as filed by the same inventor of the present invention; a secondary winding is wound around a spool in which a primary winding is buried in a flat plate and a projection of the secondary winding is pulled out axially with respect to a central core and connected to a terminal separated by a distance from the other parts to be, thereby ensuring the dielectric strength thereof.

JP 09-97 728 A further describes a three-dimensional coil assembly having a plurality of winding modules, each having a core insertion recess, and wherein magnetic cores are arranged in a stacked aggregate. Terminals of each module are arranged in projection surfaces of the unit and the cores.

GB 653 596 A further shows central channels in the middle of the coil, with which the inner terminals can be led to the outside.

STATE OF THE ART

PATENT DOCUMENTS

• Patent Document 1: Unexamined Japanese Utility Model Application Publ. JP 07-7 120 U
• Patent Document 2: WO 2008/053 613 A1

SUMMARY OF THE INVENTION

The above-mentioned transformer sheets according to Patent Documents 1 and 2 are based on the assumption that a core having a large electrical resistance is used, and therefore Patent Document 1 has a configuration such that the secondary winding comes into direct contact with the core. Patent Document 2 also has a configuration such that the terminal comes in direct contact with the core. As mentioned above, for the reason of securing the withstand voltage, the known structure is not a structure in which a stick-like core positioned at the center of the winding or a plate-like core along the winding is spaced apart from the lead of the secondary Winding is disconnected.

However, since a transformer constituting a high voltage circuit handles a large current to emit a strong magnetic field, the transformer inevitably can not help to use a core having a small electrical resistance. For this reason, it is necessary to consider insulation between a coil and a core by means of a configuration so as to provide a sufficient clearance or separation between the coil and the core. Therefore, there is a problem such that, as in Patent Document 1 or 2 discloses that the transformer having no structure to be separated by a distance between the winding and the core is not applicable to the high voltage power transformer.

The present invention has been made in order to solve the above problem, and it is an object of the invention to provide a sheet-type transformer so as to ensure insulation between a primary winding, a secondary winding and a core.

A transformer of the present invention is a transformer comprising: a magnetic member having a plate-like portion, an outer leg portion projecting on one side on a surface of the plate-like portion in a direction perpendicular to the plate-like portion, and a columnar leg portion which is provided in protruding manner at a center of the surface of the plate-like portion; a plurality of coils each forming a tubular portion into which the columnar leg portion of the magnetic member is inserted and having a flange at one end of the tubular portion; and a plurality of windings wound around the respective tubular portions of the plurality of coils; wherein the tubular portion of a coil as a part of the plurality of coils has a shape to be inserted into the tubular portion of another coil from the side of the flange, and wherein the coil is in a spiral shape having one end on the side of the periphery and an end is formed on the side of the tubular portion, and wherein the end of the coil is disposed on the side of the tubular portion which is interposed between the coil into which the tubular portion is inserted and the coil inserted therein being pulled outwardly through a gap between the tubular portions of the spool into which the tubular portion is inserted and the spool to be inserted therein; wherein on the transformer further a notch is provided at a position in contact with the columnar leg portion of the plate-like portion of the magnetic member, and wherein in the tubular portion of the coil as a portion having the flange at the one end, an extended portion which covers the notch of the magnetic member is provided at the other end of the tubular portion.

According to the invention, it is possible to provide a transformer sheet which ensures the insulation between the primary winding, the secondary winding and the core, since the insulation between the plate-like portion of the magnetic element and the winding through the flange of the coil is available the insulation between the windings is provided by the flange of another coil, the insulation between the columnar leg portion of the magnetic element and the winding is provided by the tubular portion of the coil, and further the end of the winding at the Side of the tubular portion of another winding and the magnetic element through the flange and the tubular portion of the coil is isolated.

BRIEF DESCRIPTION OF THE DRAWINGS

1 FIG. 15 is a perspective view showing a configuration of a transformer according to Embodiment 1 of the present invention. FIG.

2 is a cross-sectional view of the transformer that is in 1 is shown, which was created along a line AA.

3 is an exploded perspective view of the in 1 shown transformer.

4 FIG. 15 is a perspective view showing a configuration of a transformer according to Embodiment 2 of the invention. FIG.

5 is a cross-sectional view of the in 4 shown transformer, which was created along a line BB.

6 is an exploded perspective view of the in 4 shown transformer.

7 shows a modification of a first core: 7 (a) is a perspective view; and 7 (b) is a cross-sectional view taken along a line DD.

8th shows a configuration of an elastic member of a transformer according to Embodiment 3 of the invention: 8 (a) is a perspective view of a second coil; and 8 (b) is a cross-sectional view taken along a line EE.

9 FIG. 15 is a perspective view showing a primary winding using a plate-like cable of a transformer according to Embodiment 4 of the present invention. FIG.

10 FIG. 10 is a cross-sectional view showing a configuration of a flyback transformer according to Embodiment 6 of the invention. FIG.

11 FIG. 10 is a cross-sectional view showing another example of the flyback transformer according to Embodiment 6 of the invention. FIG.

12 FIG. 10 is a block diagram showing a configuration of a power system of an electric vehicle to which a transformer according to Embodiment 7 of the invention is applied.

BEST MODE FOR CARRYING OUT THE INVENTION

In the following, to more fully describe the invention, embodiments of the invention will be described with reference to the accompanying drawings.

Embodiment 1

1 shows an appearance of a transformer 1 according to embodiment 1, 2 shows a cross section, which was created along a line AA, and 3 shows an exploded view of components other than the windings. The transformer 1 indicates: a first coil 10 ; a sheet-like, primary winding (first winding) 30 that around the first coil 10 is wound; a second coil 20 ; a sheet-like secondary winding (second winding) 40 that around the second coil 20 is wound; a first core (magnetic element) 50 , which telescopes the first coil 10 and the second coil 20 holds; a second core (magnetic element) 60 who is in contact with the first core 50 comes; a first insulating plate 13 that the primary winding (first winding) 30 supports and the first winding 30 isolated from the other elements; a second insulating plate 23 that's an end 31 the primary winding (first winding) 30 and an end 41 the secondary winding (second winding) 40 isolated from the other elements; and an elastic element 70 ,

The first coil 10 and the second coil 20 are formed of resin or the like. The first coil 10 has a tubular section 11 and a flange 12 on, at one end of the tubular section 11 is trained. The sheet-like primary winding around which a cable is wound in a layer is around the tubular portion 11 educated. The second coil 20 includes a tubular section 21 which is smaller in diameter and longer in an axial direction than the tubular portion 11 the first coil is, and a flange 22 at one end of the tubular section 21 is trained. The leaf-like, secondary winding 40 around which the cable is wound in a layer is around the tubular portion 21 educated. In addition, on the inner edge side of the first insulating plate 13 a goat section 14 for pulling out the leading end 31 as the winding start of the primary winding 30 and a goat section 15 for pulling out the leading end 41 the winding start of the secondary winding 40 educated.

Examples of in the primary winding 30 and the secondary winding 40 cables used comprise a round cable with a circular cross section, a square cable with a square cross section and a flat cable with a rectangular cross section. When the flat cable or the square cable is used as in the illustrated example, the ratio of the cable occupying the winding space can be increased; Consequently, there is an advantage that the primary winding 30 and the secondary winding 40 can be reduced in size. In addition, in the primary and secondary winding 30 and 40 the leaders 31 and 41 arranged as the winding beginnings on the central side, while the terminal ends 32 and 42 are arranged as the coil ends on the other edge side so as to be separated from the center, which makes it possible to ensure the withstand voltage between the ends of each coil.

The first core 50 and the second core 60 are formed of a magnetic element. The combination of the first and second core 50 and 60 is referred to as an EIR core and has: a plate-like portion 51 ; a pair of opposing outer leg sections 52 and 53 protruding in a direction perpendicular to the plate-like portion 51 are provided; and a columnar leg portion 54 protruding at the center of the plate-like portion 51 is provided. The second core 60 is formed in a flat shape as in the illustrated example, and is at the tip of the columnar leg portion 54 of the first core 50 arranged. Alternatively, a core having the same shape as that of the first core 50 instead of the second core 60 can be used and a set of cores by combining the two cores, which are the first core 50 match, in such a way that the tips of the columnar leg sections 50 opposite one another.

The columnar leg section 54 of the first core 50 gets into the tubular section 21 the second coil 20 to which the secondary winding 40 is wound, inserted, the tubular section 21 continues into the tubular section 11 the first coil 10 around which the primary winding 30 is wound, inserted and the first coil 10 and the second coil 20 are arranged telescopically. Subsequently, the first insulating plate 13 at the tubular portion 11 the first coil 10 attached, the leader 31 as the winding start of the primary winding 30 and the leader 41 as the winding start of the secondary winding 40 are pulled outward and the second insulating plate 23 is at the tubular portion 21 the second coil 20 attached. Further, to the first core 50 to configure as a closed magnetic circuit becomes the second core 60 with the first core at the tips of the outer leg sections 52 and 53 and the columnar leg portion 54 combined.

In this way, since the primary winding 30 from the secondary winding 40 through the flange 12 the first coil 10 is disconnected, adjacent windings can be isolated from each other and the withstand voltage between the windings can be ensured. Additionally, if the thicknesses of the first and second coils 10 and 20 are as thin as possible, so that the withstand voltage can be ensured, the windings can be arranged closer to each other and therefore it is possible to reduce magnetic flux losses thereof, which is the performance of the transformer 1 (the coupling of the primary winding 30 and the secondary winding 40 etc.) improved. Further, the secondary winding 40 , the first core 50 and the second core 60 from each other through the second coil 20 and the second insulating plate 23 separated, which makes it possible to ensure the insulation between the winding and the cores.

The leader 31 the primary winding 30 gets out of the pull-out section 14 the first insulating plate 13 pulled out and is further in a radial direction between the first insulating plate and the second insulating plate 23 pulled to get out of the transformer 1 to be pulled out. Furthermore, the leading end 41 the secondary winding 40 that between the flanges 12 and 22 is arranged, from the extraction section 15 the first insulating plate 13 through the gap between the tubular section 11 and the tubular portion 21 is provided, pulled out and is further in the radial direction between the first insulating and the second insulating 23 pulled to get out of the transformer 1 to be pulled out. The connection end 32 the primary winding 30 and the connection end 42 the secondary winding 40 be right out of the transformer 1 pulled out. It should be noted that it is also possible connections for connecting the leading ends 31 and 41 and the leader 32 and 42 on the flanges of the first coil 10 and the second coil 20 although the illustration has been omitted.

At this time, the direction in which the leading end 31 and the connection end 32 the primary winding 30 be pulled out and the direction in which the leading end 41 and the connection end 42 the secondary winding 40 are pulled out to set in the axial direction of the columnar leg portion 54 being symmetrical, whereby it is possible to increase the distances between the windings, which makes it possible to ensure the dielectric strength between the ends.

Furthermore, the elastic element 70 also between the second insulating plate 23 and the second core 60 be arranged so that the primary winding 30 and the secondary winding 40 in the direction of the plate-like section 51 of the first core 50 be pressed. By pressing, the space between the plate-like section 51 , the primary winding 30 and the secondary winding 40 can be reduced so that preferred transformer properties can be obtained. It should be noted that when it is configured that the elastic element 70 with the function of the second insulating plate 23 is provided, whereby a direct pressing it from the elastic element 70 is performed with the insulated windings, the reduction of the number of components and the reduction thereof is improved.

In addition to the purpose of ensuring the moisture resistance, withstand voltage, etc., the transformer 1 ultimately impregnated with a resin (paint, etc.). Through this process, since the resin is the first coil 10 , the second coil 20 , the primary winding 30 , the secondary winding 40 , the first core 50 and the second core 60 fixed, can the elastic element 70 simply exert an effect as a temporary positioning element. Therefore, an elastic force having a temporary holding level for the elastic member 70 sufficient and a continuous elastic force is not needed. Incidentally, the elastic element 70 have any shape, for example, a donut-shaped, elastic element 70 , as in 3 shown to be provided or three or more elastic elements 70 can also be evenly spaced on the second insulating plate 23 be provided.

Further, it may be configured such that the first coil 10 , the second coil 20 , the first core 50 or the second core 60 is provided with a fastener (not shown) and that the transformer 1 is attached to a component with the fastener.

With the aforementioned arrangement is the transformer 1 according to Embodiment 1, for exhibiting: the first coil 10 with the tubular section 11 and the flange 12 at an opening end of the tubular section 11 is trained; the first insulating plate 13 that on the other opening of the first coil 10 is provided and the flange 12 the first coil 10 opposite; the second coil 20 holding the tubular section 21 which is smaller in diameter and longer in the axial direction than the tubular portion 11 the first coil 10 is, and the flange 22 at an opening end of the tubular section 21 is trained; the first core 50 comprising the plate-like portion 51 , the pair on opposite outer leg sections 52 and 53 protruding in the direction perpendicular to the plate-like portion 51 are provided, and the columnar leg portion 54 protruding at the center of the plate-like portion 51 is provided, and the telescoping manner, the tubular portion 21 the second coil 20 , the tubular section 11 the first coil 10 and the first insulating plate 13 holds, in which the columnar leg portion 54 is introduced in this order; the flat second core 60 that with the first core 50 at the tips of the columnar leg section 54 and the outer leg portions 52 and 53 combined; the primary winding 30 which has the shape of a sheet surrounding the tubular portion 11 the first coil 10 is wound and from both sides of the flange 12 the first coil 10 and the first insulating plate 13 be supported; and the secondary winding 40 which has the shape of a sheet surrounding the tubular portion 21 the second coil is not inserted into the tubular portion of the first coil, and from both sides of the flange 22 the second coil 20 and the flange 12 the first coil 10 be supported. Therefore, it becomes possible to arrange the winding start and the winding end of each winding at positions spaced apart from each other (central side and outer edge side), which makes it possible to ensure the withstand voltage between the ends of the windings. In addition, the plate-like portion of the core and the windings can be separated and insulated from each other by the flanges of the coils and the insulating plates. Further, the pillar-shaped leg portion of the core and the coils may be separated and insulated from each other by the tubular portions of the coils.

Additionally, it is configured to be the leading end 31 the primary winding 30 from the extraction section 14 in an open way in the first insulating plate 13 is provided in the gap between the first insulating plate 13 and the second insulating plate 23 is pulled out and the leader 41 the secondary winding 40 gets out of the pull-out section 15 in an open way in the first insulating plate 13 is provided in the gap between the first insulating plate 13 and the second insulating plate 23 pulled out while passing through the gap between the tubular sections 11 and 21 the first and second coil 10 and 20 runs. This makes it possible to extract the end as the winding start through the space between the coils; consequently, the end may be disconnected as the start of winding and isolated from the other winding and cores by the flanges and tubular portions of the coils and insulating plates.

Consequently, it is possible to provide a sheet-like type of transformer in which the insulation between the primary winding, the secondary winding and the cores is ensured. Also, since the windings can be arranged close to each other by reducing the thicknesses of the flanges of the coils serving to insulate the windings from each other, it is possible to reduce the loss of magnetic flux thereof, which makes it possible to improve the performance of the transformer.

Further, according to Embodiment 1, since the direction in which the leading end 31 and the connection end 32 the primary winding 30 be pulled out and the direction in which the connection end 41 and the connection end 42 the secondary winding 40 are pulled out to be symmetrical to the axial direction of the columnar leg portion 54 of the first core 50 To be, it is possible to increase the distance between the ends of both windings, which allows to ensure the dielectric strength between the ends.

Further, according to Embodiment 1, since the transformer 1 is formed to the elastic element 70 which is used to push the primary winding 30 and the secondary winding 40 in the direction of the plate-like section 51 of the first core 50 is to exhibit, it is possible to reduce the space between the cores and the windings, which makes it possible to obtain preferred characteristics of the transformer.

Further, according to Embodiment 1, since the flat cable in the primary winding 30 and the secondary winding 40 is used, the space factor of the winding is increased to reduce unnecessary spaces, whereby the transformer is reduced in size.

It should be noted that it is also possible to use a choke coil by using the core and the coil of the transformer 1 according to the embodiment 1 described above.

Embodiment 2

4 shows an appearance of a transformer 1 according to embodiment 2, 5 shows a cross section, which was created along a line BB and 6 shows an exploded view of components except the windings. In 4 to 6 be parts that are the same or equivalent to those in 1 to 3 are denoted by the same reference numerals. The transformer 1 according to embodiment 2 has transformers 1a and 1b each having a first core (magnetic element) 50 comprising, telescopically, a first coil 10 to which one secondary winding (first winding) 40 is wound, and a second coil 20 which one primary winding (second winding) 30 is wound, holds and the transformer is connected by connecting the transformers 1a and 1b configured so that the first cores 50 show each other. It should be noted that two pairs of the primary winding 30 and the secondary winding 40 are arranged to be symmetrical with respect to an opposite plane C.

The first core 50 is called a PQ kernel, notches 55 and 56 by notching a pair on opposite sides of the plate-like portion 51 formed and the peripheral surface of a columnar leg portion 54 extends to the plate-like portion. Such extended surfaces 57 and 58 are arranged to be symmetrical with respect to the axial direction of the columnar leg portion 54 to be.

The second coil 20 includes a tubular section 21 and a flange 22 at one end of the tubular section 21 is trained. In addition, the extended sections 24 and 25 formed in the second coil, so that a part of the end on the flangeless side of the tubular portion 21 is extended. The extended sections 24 and 25 cover the extended surfaces 57 and 58 in that it the peripheral surface of the columnar leg portion 54 extend to the plate-like portion and serve as partitions for isolating the leading ends 31 and 41 from the first core 50 ,

The leader 41 the secondary winding 40 gets out of the pull-out section 14 in an open fashion in the insulating panel section 13 is provided to the extended section 24 pulled out. The leader 31 the primary winding 30 passes through the gap between the tubular sections 11 and 21 is provided, in the axial direction and is from the extraction section 15 in an open fashion in the insulating panel section 13 is provided to the extended section 25 pulled out. The connection end 32 the primary winding 30 and the connection end 42 the secondary winding 40 be right out of the transformer 1 pulled out.

At this point, the direction in which the leader ends 31 and the connection end 32 the primary winding 30 pulled out together, and the direction in which the leader 41 and the connection end 42 the secondary winding 40 withdrawn, adjusted to with respect to the axial direction of the columnar leg portion 54 Being symmetrical, it is thereby possible to increase the distance between the ends of each winding, which makes it possible to ensure the withstand voltage between the ends. In addition, as the leaders 31 and 41 and the extended surfaces 57 and 58 that the peripheral surface of the columnar leg portion 54 of the first core 50 extend to the plate-like portion, through the extended portions 24 and 25 the second coil 20 can be divided, the insulation between the windings and the core can be ensured.

An elastic element 70 is between the two pairs of telescopic structures, that is, between the flanges on the sides of the transformer 1a . 1b arranged. In this way, the two pairs of windings each in the direction of the plate-like portion 51 the corresponding first core 50 are pressed and therefore the positional relationship between the plate-like sections 51 , the primary winding 30 and the secondary winding 40 right in each of the transformers 1a . 1b and also the characteristics of it will be the same. In such a way can the loads of transformers 1a . 1b to be compensated; without concentrating the load on one of the transformers, it can be avoided that only a part of them is exposed to a high temperature. Because of this, it is possible that the transformers 1 work without a transformer 1 to provide a local load, which makes it possible to improve the reliability of the transformer.

7 shows a modification of the first core 50 : 7 (a) is a perspective view thereof; and 7 (b) Fig. 16 is a cross-sectional view thereof taken along the line DD. In the plate-like section 51 of the first core 50 is the central section of the columnar leg section 54 is provided, thicker, while both end sections, with the outer leg sections 52 and 53 are provided, are thinner. A magnetic flux B coming from the primary winding 30 goes out, passes through the columnar leg section 54 in the axial direction and the magnetic flux B / 2 reaches each end portion of the plate-like portion 51 over the central section of it. At this time, if the Cross-sectional area at each position of the plate-like portion 51 is not less than 1/2 of the cross-sectional area of the columnar leg portion, the magnetic flux is not hindered and if the product has a width l and a thickness t from each position of the plate-like portion 51 is the same size as 1/2 of the cross-sectional area of the columnar leg portion, there is no problem in terms of the characteristics of the transformer. Accordingly, in the case of the first core 50 because the width l of the plate-like section 51 gradually from the side of the columnar leg section 54 towards the outer leg sections 52 and 53 Increased, the properties of the transformer are not affected, even if the thickness t is reduced as the width increases. Consequently, since the plate-like section 51 opposite to the winding, with a proper amount of magnetic material at each position of the first core 50 can be formed, the weight of the core can be reduced without deteriorating the performance of the transformer.

With the aforementioned arrangement is the transformer 1 according to Embodiment 2, to have: the first coil 10 with the tubular section 11 and the flange 12 at an opening end of the tubular section 11 is trained; the first insulating plate 13 at the other opening of the first coil 10 is provided and the flange 12 the first coil 10 is opposite; the second coil 20 holding the tubular section 21 which is smaller in diameter and longer in the axial direction than the tubular portion 11 the first coil 10 is, the flange 22 at one end of the tubular section 21 is formed, and the extended sections 24 and 25 comprising a portion of the other end of the tubular section 21 extend; the first core 50 formed of the magnetic element with the plate-like portion 51 is provided, the pair on opposite outer leg portions 52 and 53 which is provided in the above manner in the direction perpendicular to the plate-like portion 51 is, the columnar leg section 54 protruding at the center of the plate-like portion 51 is provided, and the surfaces 57 and 58 by notching the sides of the plate-like portion 51 and by extending a part of the peripheral surface of the columnar leg portion 54 and the telescopically tubular portion 21 the second coil 20 and the tubular section 11 the first coil 10 into the columnar leg section 54 is introduced, holds and the surfaces 57 and 58 comprising a portion of the peripheral surface of the columnar leg portion 54 extend that with the extended sections 24 and 25 the second coil 20 is covered; the secondary winding 40 which has the shape of a sheet surrounding the tubular portion 11 the first coil 10 is wound and from both sides of the flange 12 the first coil 10 and the first insulating plate 13 be supported; and the primary winding 30 which has the shape of a sheet surrounding the tubular portion 21 the second coil 20 which is not wrapped in the columnar section 11 the first coil 10 is introduced and from both sides of the flange 22 the second coil 20 and the flange 12 the first coil 10 be supported, the end 41 at the side of the tubular portion of the secondary winding 40 from the one pull-out section 14 pulled out in an open manner in the first insulating plate 13 towards the one notch 57 of the first core 50 is provided and the end 31 at the side of the tubular portion of the primary winding 30 passes through the gap between the tubular sections 11 and 21 the first and second coils 10 and 20 , which are attached to each other, and will come out of the other pull-out section 15 that in an open way in the first insulating plate 13 is provided, in the direction of the other notch 58 of the first core 50 pulled out. Therefore, similar to the first embodiment 1 described above, the plate-like portion of the core and the coils can be separated and insulated from each other by the flanges of the coils and the insulating plates, and the columnar leg portion of the core and the coils can be isolated and separated from each other by the tubular portions the coils are isolated. Consequently, it becomes possible to arrange the winding start and the winding end of each winding at positions spaced apart from each other (central side and outer edge side), which makes it possible to ensure the withstand voltage between the ends of the windings.

Additionally, it is configured to be the leading end 41 the secondary winding 40 from the extraction section 14 that in an open way in the first insulating plate 13 is provided, in the direction of the notch 57 is pulled out of the first core (the surface that extends a part of the peripheral surface of the columnar leg portion), and that the leading end 31 the primary winding 30 through the gap between the tubular sections 11 and 21 the first and second coil 10 and 20 runs and out of the extraction section 15 that in an open way in the first insulating plate 13 is provided, in the direction of the notch 58 of the first core 50 is pulled out (the surface that extends a part of the peripheral surface of the columnar leg portion). For this reason, it becomes possible to pull the leading end of each winding out of the transformer without the leading end to pass through the space between the flanges of the coils; consequently, the space between the core and the coil can be reduced, and the core and the coil can be brought closer to each other, and therefore it is possible to reduce the leakage of the magnetic flux thereof, which makes it possible to improve the performance of the transformer. In addition, the end may be separated as the winding start of the winding and insulated from the other winding and the cores by the insulating plates and the extended portions, the flanges and the tubular portions of the coils.

Consequently, similarly to the first embodiment 1 described above, it is possible to provide the sheet-type transformer in which the insulation between the primary winding, the secondary winding and the cores is ensured. In addition, since it is possible to reduce the thickness of the flange of the coil to insulate the coils from each other to arrange the coils close to each other, the leakage of the magnetic flux can be reduced, thereby improving the performance of the transformer.

In addition, according to Embodiment 2, since the direction in which the leading end 31 and the connection end 32 the primary winding 30 be pulled out, and the direction in which the leading end 41 and the connection end 42 the secondary winding 40 can be adjusted to be symmetrical to the axial direction of the columnar leg portion 54 of the first core 50 To be, it is possible to increase the distance between the ends of both windings, which makes it possible to ensure the dielectric strength between the ends.

Further, according to Embodiment 2, it is configured such that the transformer 1 has the two pairs of transformers 1a and 1b , each one the first core 50 comprising, telescopically, the first and second coils 10 and 20 holds as a set of transformers, and that the tip surfaces of the columnar leg portions 54 the two pairs of the first nuclei 50 face each other and the primary windings 30 and the secondary windings 40 are arranged to be symmetrical with respect to the opposite plane C. For this reason, the characteristics of the transformer 1a and the transformer 1b equal to each other, whereby a parallel connection of the windings is simplified. Accordingly, if the two primary windings 30 be connected in parallel and also the two secondary windings 30 can be connected in parallel, whereby the cross-sectional area of each cable is doubled, a current flowing therethrough can be doubled.

Further, if the two primary windings 30 be connected in series, and also the two secondary windings 40 can be connected in series, whereby the number of turns of each cable is doubled, the degree of freedom of the number of turns and the turns ratio can be increased so as to improve the characteristics (coupling and the like) of the transformer.

Further, according to Embodiment 2, since it is configured so that the transformer 1 the elastic element 70 that has the two pairs of the primary winding 30 and the secondary winding 40 in the direction of the plate-like sections 51 the first nuclei 50 Pressing, it is possible to reduce the distance between the cores and the windings, which makes it possible to obtain advantageous properties (the coupling and the like) of the transformer.

It should be noted that the transformer also by combining the two transformers 1 that can be configured in Embodiment 1 described above. In this case, the second core 60 not with the first core 50 combined, but the first two cores 50 are combined with each other. In particular, the first two nuclei lie 50 , which telescopically the first and second coil 10 and 20 hold, facing each other and are brought into contact with each other and the elastic element 70 is between the opposing second insulating plates 23 arranged. Even in the case of such a configuration, if the two primary windings 30 be connected in parallel and also the two secondary windings 40 can be connected in parallel, whereby the cross-sectional area of each cable is doubled, a current flowing therethrough can be doubled. Alternatively, if the two primary windings 30 be connected in series and also the secondary windings 40 in series, whereby the number of turns of each cable is doubled, the degree of freedom in the number of turns and the turns ratio can be increased so as to improve the characteristics (coupling and the like) of the transformer.

It should be noted that in Embodiment 2 described above, although the one transformer 1 by combining the transformers 1a and 1b , each using the notched core is configured, it is also possible the transformer 1 only through the transformers 1a and 1b to configure with a pair of windings. In this case, to the core as one form closed magnetic circuit, for example, the first core 50 of the transformer 1a may be brought into contact with a PQ core having the same shape, or may be in contact with a flat second core 60 , as in 1 to 3 be brought shown.

Embodiment 3

Although the above embodiments 1 and 2 have the configuration in which the separate elastic member 70 is used, the elastic member may also be integrally formed with the coil as shown in the present embodiment 3.

8th shows a configuration of the elastic elements 71 and 72 a transformer according to Embodiment 3: 8 (a) is a perspective view of a second coil 20 and 8 (b) Fig. 16 is a cross-sectional view thereof taken along the line EE. It should be noted that, since the transformer of the present embodiment 3 has the same configuration as that of the transformer 1 who in 4 to 6 is shown, except the configuration of the elastic member, a description below with reference to 4 to 6 he follows.

The elastic elements 71 and 72 are flat spring-like projections and are made by piercing the flange 22 the second coil 20 educated. Due to the flat spring-like elastic elements 71 and 72 become the second coil 20 itself and the other second coil 20 that face each other and come into contact with each other, toward the first core 50 pressed. If a section of the flange 22 the second coil 20 is cut open, becomes an opening, at which the primary winding 30 is exposed, formed on the cut portion; however, since the same primary winding 30 around the other second coil 20 which are wound on each other and come into contact with each other is wound, the two primary windings are arranged at the same potential, so that no electrical problem occurs. In addition, as mentioned above, because the transformer 1 lastly impregnated with the resin, an elastic force having a temporary holding level is sufficient for the elastic members 71 and 72 and a continuous elastic force is not needed for it.

Incidentally, even in the transformer 1 According to the embodiment 1 described above, the elastic members 71 and 72 also in the second insulating plate 23 instead of the elastic element 70 be formed.

As mentioned above, according to Embodiment 3, since the elastic members 71 and 72 be provided by the projections in the flange 22 the second coil 20 are formed, it is possible to omit the element used only for pressing each winding toward the plate-like portion of the core, resulting in a simplified operation thereof, thereby lowering the cost.

Embodiment 4

Although the above-described Embodiments 1 and 2 have the configuration such that the flat cable is a cable of the primary winding 30 and the secondary winding 40 is used as described in the present embodiment 4, a cable having a different shape may also be used.

For example, a wire rod in which a plurality of cables are bundled (stranded cable) or a wire rod in which a plurality of cables are arranged in parallel can also be used in the primary winding 30 and the secondary winding 40 be used. In this case, it is possible to avoid a loss due to skin effects, and thereby it is possible to avoid a loss during the application of energy at a high frequency, which makes it possible to increase the operating frequency of the transformer.

In this way it becomes possible to reduce the number of turns of the winding, which makes it possible to reduce the size of the transformer.

Alternatively, a conductive flat plate, for example, a plate-like cable formed in a spiral shape, may also be used in the primary winding 30 and the secondary winding 40 be used. 9 is a perspective view showing a primary winding 30 using a plate-type cable shows. The spiral plate material can be easily formed, for example, by a punching method. On the other hand, the ends are bent in a predetermined drawing direction to a guide end 31 and a connection end 32 train. The secondary winding 40 can also be formed in the same way, although the presentation is omitted.

When such a plate material cut out in the spiral shape is used, it becomes possible to reduce the number of cables that are wound in parallel to increase the cross-sectional area of the coil, so that the size of the transformer can be reduced. It should be noted that when a thick plate material is used, it is possible to increase the cross-sectional area of the coil to allow the passage of a large current, so that a transformer for high power can be constructed.

Embodiment 5

As in 1 to 7 shown is the secondary winding 40 on the side of the plate-like section 51 of the first core 50 arranged and the transformer 1 is used as a forward transformer.

• (1) Ein Strom verläuft durch die primäre Wicklung 30;
• (2) ein magnetisches Feld wird in der Umgebung der primären Wicklung 30 als Antwort auf das Hindurchfließen des Stroms durch die primäre Wicklung 30 erzeugt;
• (3) ein Strom in einer Richtung, die einen magnetischen Fluss aussendet, der einen magnetischen Fluss aufhebt, der von der primären Wicklung 30 ausgesendet wird, verläuft durch die sekundäre Wicklung 40; und
• (4) der magnetische Fluss, der von der primären Wicklung 30 ausgesendet wurde, wird mit dem magnetischen Fluss ausgeglichen, der von der sekundären Wicklung 40 ausgesendet wurde.

The following (1) to (4) describe an overview of a current passing through the primary winding, a magnetic flux being generated, and a current passing through the secondary winding of the forward transformer:

• (1) A current passes through the primary winding 30 ;
• (2) a magnetic field is in the environment of the primary winding 30 in response to the passage of current through the primary winding 30 generated;
• (3) a current in a direction emitting a magnetic flux canceling a magnetic flux coming from the primary winding 30 is sent out, passes through the secondary winding 40 ; and
• (4) the magnetic flux flowing from the primary winding 30 is emitted, is balanced with the magnetic flux coming from the secondary winding 40 was sent out.

Consequently, the size of the current passing through the primary winding 30 passes, by the size of the current passing through the secondary winding 40 runs, determined.

Claims (14)

Transformer, comprising: a magnetic member having a plate-like portion, an outer leg portion projectingly provided on one side on a surface of the plate-like portion in a direction perpendicular to the plate-like portion, and a columnar leg portion protruding at a center of the surface the plate-like portion is provided; a plurality of coils each forming a tubular portion into which the columnar leg portion of the magnetic member is inserted and having a flange at one end of the tubular portion; and a plurality of windings wound around the respective tubular portions of the plurality of spools; wherein the tubular portion of a coil as a part of the plurality of coils has a shape to be inserted into the tubular portion of another coil from the side of the flange, and wherein the winding is formed in a helical shape with one end on the side of the circumference and one end on the side of the tubular portion, and the end of the winding on the side of the tubular portion between the coil into which the tubular portion is inserted, and the coil which is inserted therein is disposed outwardly through a gap between the tubular portions of the coil into which the tubular portion is inserted and the coil to be inserted therein; wherein a notch is further provided on the transformer at a position in contact with the columnar leg portion of the plate-like portion of the magnetic member, and wherein in the tubular portion of the one coil as a portion having the flange at the one end, an extended portion covering the notch of the magnetic member is provided at the other end of the tubular portion. A transformer according to claim 1, wherein a notch of the magnetic member is provided at two locations in a symmetrical direction with respect to an axial direction of the columnar leg portion of the magnetic member. A transformer according to claim 1, further comprising a plate-like magnetic member which comes into contact with the tips of the columnar leg portion and the outer leg portion of the magnetic element. A transformer according to claim 1, comprising two sets of the magnetic member, the plurality of coils, and the plurality of windings, wherein between the two sets the tips of the columnar leg portions of the magnetic members are brought into contact with each other, tips of the outer leg portions of the magnetic members are brought together and the windings are arranged to be symmetrical with respect to a contact surface thereof. A transformer according to claim 1, further comprising an elastic member for urging the windings toward the plate-like portion of the magnetic member. A transformer according to claim 5, wherein the elastic member is a projection formed on the flange of the coil. A transformer according to claim 1, wherein a part of the plurality of windings is a pair of a primary winding and a secondary winding. A transformer according to claim 7, wherein one end of the primary winding and one end of the secondary winding are pulled out in an opposite direction with respect to an axial direction of the columnar leg portion of the magnetic member. A transformer according to claim 7, wherein a square cable or a flat cable is used in at least one of the plurality of windings. A transformer according to claim 7, wherein a rolled cable in which a plurality of cables are bundled is used in at least one of the plurality of windings. A transformer according to claim 7, wherein a plate-like cable forming a conductive flat plate in a spiral shape is used in at least one of the plurality of windings. A transformer according to claim 7, wherein the secondary winding is disposed on the side of the plate-like portion of the magnetic member to form a forward transformer. A transformer according to claim 7, wherein the primary winding is disposed on the side of the plate-like portion of the magnetic member to form a flyback transformer. A transformer according to claim 1, wherein the transformer is used in a vehicle-mounted component.

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